Portable electronic device

ABSTRACT

A drop detection part that detects drop into the water, a light emission part, and a light-emission control circuit that makes the light emission part emit light when the drop detection part detects the drop into the water. Also, the light emission part may be disposed on the side to be turned up by buoyancy when the device is dropped into the water and the drop detection part may be disposed on the side to be turned down in the case of the drop into the water, for example.

CROSS REFERENCE TO RELATED APPLICATION

The present invention is related to, claims priority from, andincorporates by reference Japanese Patent Application No. 2010-183656,filed on Aug. 19, 2010.

TECHNICAL FIELD

The present invention relates to a portable electronic device andparticularly to a portable electronic device that can float on watereven if it is dropped into the water.

BACKGROUND

There are many portable electronic devices used close to water such asmarine transceivers and the like. Since this type of electronic devicescan be accidentally splashed with water or dropped into the water,water-proof devices so that water cannot enter the insides have been putinto practice. Also, if the device sinks in the water when being droppedinto the water, it cannot be recovered. A floating-type device to stayafloat when being dropped into the water is also proposed, as disclosedby Japanese Laid-Open Patent Application Publication No. H04-135038.

However, at night or when visibility is poor, even if an electronicdevice floats on the water surface, it is likely that the device cannotbe found. In such case, there has been a problem that the electronicdevice cannot be recovered even though it is floating on the water.

The present invention has an object to provide a portable electronicdevice that can be easily found on the water surface even at night or ifvisibility is poor.

SUMMARY

A portable electronic device of the present invention includes a dropdetection part that detects drop of the device into the water, a lightemission part, and a light-emission control circuit that makes the lightemission part emit light when the drop detection part detects drop intothe water.

In a preferred embodiment of the present invention, the light emissionpart is disposed on the side to be turned up by buoyancy when the deviceis dropped into the water, and the drop detection part is disposed onthe side to be turned down when the device is dropped into the water.

In a preferred embodiment of the present invention, the electronicdevice has the buoyancy by which at least the light emission part comesup to the water surface when the device is dropped into the water.

In a preferred embodiment of the present invention, an antenna isdisposed on a front side of the top face, and a speaker is disposed onthe front face, the drop detection part is disposed inside a speakergrill that covers the front of the speaker, and the light emission partis disposed on the bottom face.

In a preferred embodiment of the present invention, the light-emissioncontrol circuit includes a delay circuit that keeps the light emissionpart emitting light for a predetermined time after the drop detectionpart does not detect drop into the water any longer.

In a preferred embodiment of the present invention, the electronicdevice has a housing including a front housing, a rear housing and agasket fitted to a joined part of the front housing and the rearhousing, furthermore. And the light emission part includes a translucentsection formed at a part of the gasket and a light emittingsemiconductor element disposed inside the housing.

According to this invention, since the light emission part emits lightwhen the portable electronic device is dropped into the water, even atnight or if visibility is poor, a user can easily find the portableelectronic device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a appearance view of a transceiver, which is an embodiment ofthe present invention.

FIG. 1B is a appearance view of the transceiver.

Fig. 1C is a appearance view of the transceiver.

FIG. 2A is a structural diagram of the vicinity of a speaker grill ofthe transceiver.

FIG. 2B is a structural diagram of the vicinity of a speaker grill ofthe transceiver.

FIG. 3A is a structural diagram of the vicinity of the speaker grill ofthe transceiver.

FIG. 3B is a structural diagram of the vicinity of the speaker grill ofthe transceiver.

FIG. 4 is an internal structural diagram of a lower part of thetransceiver.

FIG. 5 is a circuit diagram of an LED lighting control circuit of thetransceiver.

FIG. 6 is a diagram illustrating an attitude when the transceiver isdropped into the water.

FIG. 7A is a diagram illustrating another embodiment of the vicinity ofthe speaker grill of the transceiver.

FIG. 7B is a diagram illustrating another embodiment of the vicinity ofthe speaker grill of the transceiver.

EXPLANATION OF REFERENCE NUMERALS

“1” transceiver

“11” housing

“11A” front housing

“12” antenna

“13” gasket

“13A” translucent section

“16” speaker grill

“21A” projection (of housing)

“30” speaker

“32” fin (of speaker grill)

“35” electrode

DETAILED DESCRIPTION

FIG. 1 are appearance views of a transceiver, which is an embodiment ofthe present invention. FIG. 1A is a front view of the transceiver, FIG.1B is a left side view of the transceiver, and FIG. 1C is a bottom viewof the transceiver.

This transceiver 1 is a hand-held device for maritime communications. Afeature of this transceiver 1 is that the transceiver does not sink butfloats even if it is dropped into the water and when it is dropped intothe water, a part of a housing flashes so that a user can easily find iteven at night or if visibility is poor.

The transceiver 1 presents an appearance having a main body 10 includinga housing 11 and an antenna 12 disposed on the top face of the housing11. The housing 11 has a front housing 11A and a rear housing 11B. Thefront housing 11A and the rear housing 11B are joined with a gasket 13between them.

The front housing 11A includes a substantially planar front panel 20,and a left face plate 21, a right face plate 22, an top face plate 23and a bottom face plate 24 rising rearward substantially at a rightangle from a peripheral edge of the front panel 20. On edges of the leftface plate 21, the right face plate 22, the top face plate 23, and thebottom face plate 24, grooves into which the gasket 13 is inserted areformed. The rear housing 11 B has a shape of a lid in which upper,lower, right and left rims gently rise to the front from the rear faceon which a clip 15 is disposed. In the edges of the rims, grooves intowhich the gasket 13 is inserted are formed.

By joining the front housing 11A and the rear housing 11B together withthe gasket 13 in their respective groove parts between them, intrusionof water into the inside of the housing 11 through the joined partbetween the front housing 11A and the rear housing 11B is prevented.

The gasket 13 is in the loop shape and is sandwiched over the entireperiphery between the edge of the front housing 11A and the edge of therear housing 11B. The gasket 13 is exposed to the outside substantiallyover the entire periphery between the front housing 11A and the rearhousing 11B, but the left face plate 21 and the right face plate 22 haveprojections 21A and 22A on the edges close to their bottoms, and thegasket 13 is hidden from the outside only for the parts of theprojections 21A and 22A.

The loop-shaped gasket 13 consists of a translucent section 13A of milkwhite and a opaque section 13B of blue. The gasket 13 is attached to thehousing 11 so that the translucent section 13A is located closer to thebottom face than the projections 21A and 22A and the opaque section 13Bis located closer to the top face than the projections 21A and 22A. As aresult, a spot where color is roiled at the boundary between thetranslucent section 13A and the opaque section 13B is hidden behind theprojections 21A and 22A, and appearance is maintained while colorseparation to two colors of the gasket 13 is realized.

On the lower part inside the main body 10 (housing 11), an LED 41 (SeeFIG. 4) is disposed, and when the transceiver 1 is dropped into thewater, the LED 41 flashes. By means of the light, the translucentsection 13A of the gasket 13 becomes bright seen from the outside. TheLED 41 and the translucent section 13A correspond to the light emissionpart of the present invention.

The antenna 12 is disposed closer to the front face on the top face ofthe housing 11, that is, on the top face of the front housing 11A,directed upward. The antenna 12 is a rod-shaped antenna having acoil-shaped antenna wire contained in a resin pipe. The antenna wire isa copper wire or an iron wire, which has a weight. By means of theweight of the antenna 12, the weight balance of the entire transceiver 1is biased to the upper front.

On the front panel 20 of the front housing 11A, a speaker grill 16, adisplay 17, and a plurality of keys 18 are disposed in above order.Also, a PTT switch 19 is disposed on the right face plate 22, a chargingconnector 14 covered by a water-proof cap on the left side of theantenna 12 on the top face plate 23, and a clip 15 at the center of therear housing 11B, respectively. Inside the speaker grill 16 of the frontpanel 20, as shown in FIGS. 2 and 3, a speaker 30 and a pair ofelectrodes 35 that detects drop of the transceiver 1 into the water aredisposed.

A configuration in the vicinity of the speaker grill 16 of the fronthousing 11A will be described referring to FIGS. 2 and 3. FIGS. 2 and 3show different embodiments in which mounting forms of the electrodes 35are different from each other. FIGS. 2A and 3A are left sectional viewsin the vicinity of the speaker grill 16 of the front housing 11A., whileFIGS. 2B and 3B are views of the vicinity of the speaker grill 16 of thefront housing 11A seen from behind the speaker 30.

On the upper part of the front panel 20 of the front housing 11A, agrill fitting hole 111, which is approximately square is formed on theouter surface of the front housing 11A with a depth of approximatelyhalf of a thickness of the front housing 11A. Also, on the inner surfaceof the front housing 11A opposing the grill fitting hole 111, a speakerfitting hole 112 is formed circularly into which the speaker 30 isfitted. The speaker fitting hole 112 is formed opposing the center ofthe grill fitting hole 111 smaller than the grill fitting hole 111. Byforming of the grill fitting hole 111 and the speaker fitting hole 112,a circular opening part in the shape of the speaker 30 is formed in thefront housing 11A.

The speaker grill 16 is fitted in and fixed to the grill fitting hole111 from outside the front housing 11A. The speaker grill 16 has aninverted U-shaped frame 33 and a plurality of fins 32 formed in thelateral direction inside the frame 33. In the speaker fitting hole 112,a dust proof net 31 and a water-proof speaker 30 are fitted, and anadhesive 34 is applied on the outer periphery of the speaker 30. Bymeans of this adhesive 34, the speaker 30 and the net 31 are fixed tothe front housing 11A, and a gap is blocked. Moreover, the pair ofelectrodes 35 are disposed, which leads from the inside of the fin 32 tothe inside of the front housing 11A are disposed.

In the embodiment in FIG. 2, the shape of the electrode 35 is a straightpin shape. The pair of electrodes 35 are disposed linearly penetratingtwo through holes 113 formed right and left of the speaker fitting hole112 of the front housing 11A, respectively. The through hole 113 isformed on the grill fitting hole 111, that is, on the back side of thespeaker grill 16 and at a position outside the speaker fitting hole 112.Also, an adhesive 36 is applied on the periphery of the through hole 113inside the front housing 11A. The adhesive 36 fixes the electrodes 35and also seals intrusion of water through the through hole 36.

In the embodiment in FIG. 3, the pair of electrodes 35 are alignedvertically on the right side of the speaker 30 seen from the inside ofthe front housing 11A, and each tip of the electrodes 35 respectivelyprotrudes to the inside of the two fins 32 aligned vertically. Eachelectrode 35 consists of a conductor strip, and is formed in astair-like shape having two steps by folding up and down the conductorstrip. The tip of the electrode 35 penetrates the through hole 113 andprotrudes to the outside of the housing 11, and the first step face isbrought into contact with the back side of the front housing 11A so asto prevent removal of the electrode 35 to the outside of the housing 11.Also, the adhesive 36 is applied on the periphery of the through hole113 inside the front housing 11A. The adhesive 36 fixes the electrode 35and seals intrusion of the water through the through hole 113. Byattaching the electrode 35 in this way, the second step face of theelectrode 35 is located in the air floating from the inside of the fronthousing 11A. As a result, even if the lead wire is soldered on thesecond step face, the front housing 11A is not melted.

In either of the embodiments in FIGS. 2 and 3, the pair of electrodes 35are disposed with a distance or in a positional relationship such thatboth are electrically conducted when they sink under the water and notelectrically conducted at such wet of some of droplets. The pair ofelectrodes 35 corresponds to the drop detection part of the presentinvention.

FIG. 4 is a diagram for explaining a partial internal structure of thetransceiver 1. This diagram is that of the inside of the housing 11 seenfrom the left side. A print circuit board 40 on which various circuitsare mounted is disposed on the front face side inside the housing 11 (inthe front housing 11A), and the LED 41 is mounted on the lower end partthereof. The LED 41 is a self-flashing type LED and its turning-on(flashing)/turning-off is controlled by a lighting control circuit shownin FIG. 5. Since the self-flashing LED has a flashing circuit inside, anoptical axis 42 is inclined, and as shown in the figure, only bymounting the LED 41 upright to the board, the optical axis 42 can beexactly directed to the direction of the translucent section 13A of thegasket 13. As a result, when the LED 41 is turned on, the translucentsection 13A of the gasket 13 is directly illuminated by the light, andit appears from the outside that the translucent section 13A emitslight.

FIG. 5 is a diagram illustrating a lighting control circuit of the LED41. This lighting control circuit corresponds to a light-emissioncontrol circuit of the present invention. This lighting control circuitis a circuit constituted such that a Pch MOS field-effect transistor(FET) Q1 and an NPN transistor Q2 are turned on when the pair ofelectrodes 35 (35A and 35B) are electrically conducted each other, andthe LED 41 connected between a collector of the transistor Q2 and apower source is made to flash (lighted).

The power source (lithium-ion battery) and this circuit are directlyconnected to each other without through a power switch, and even if thepower switch is off, the LED 41 is made to flash if the transceiver 1 isdropped into the water. A resistor R1, a resistor R2 and the pair ofelectrodes 35 (35A and 35B) are connected in series between the powersource and the ground. A connection point between the resistor R1 andthe resistor R2 is connected to the gate of the FET Q1. The source ofthe FET Q1 is connected to the power source, and a forward-directiondiode D1 and a capacitor C1 are connected in series between the drain ofthe FET Q1 and the ground. A connection point between the diode D1 andthe capacitor C1 is connected to the base of the transistor Q2. Thetransistor Q2 is a transistor for digital operation that incorporates aresistor, and a resistor is connected in series to the base. The LED 41is connected between the collector of the transistor Q2 and the powersource, and the emitter of the transistor Q2 is grounded.

When the transceiver 1 is dropped into the water and the electrodes 35Aand 35B are electrically conducted to each other, a power voltagedivided at the resistors R1 and R2 is applied to the gate of the FET Q1.As a result, the FET Q1 is turned on, and the capacitor C1 is quicklycharged through the diode D1. By the charging of the capacitor C1, abase voltage of the transistor Q2 is raised, and the transistor Q2 isturned on. By the turning-on of the transistor Q2, an electric currentflows through the LED 41 and the LED 41 is made to flash.

When the transceiver 1 is taken out of the water and the electricalconduction between the electrodes 35A and 35B is shut off, the FET Q1 isturned off, but since the capacitor C1 has been charged close to thepower voltage, the transistor Q2 is kept in the ON state until thecapacitor C1 is discharged through the base/emitter of the transistorQ2. The capacitor C1 is chosen based on the capacitance so as to keep Q2in the ON state for 30 to 60 seconds after shut-off of the electrodes35A and 35B. As a result, even if a user takes up the transceiver 1 outof the water surface in a dark environment, the LED 41 keeps flashing soas not to miss the transceiver. The transistor Q2 and the capacitor C1correspond to the delay circuit of the present invention.

Since the transceiver 1 has been saved an entire weight by using a largecapacity lithium-ion battery with a light weight as a power source andthe like and has the housing 11 of the water-proof structure, thetransceiver floats on the water surface without sinking even if it isdropped into the water. Also, as shown in FIGS. 1 to 4, since componentswith weights such as the speaker 30, the print circuit board 40, theantenna 12 and the like are disposed on the front face side in a biasedmanner, the center of gravity of the transceiver 1 is close to the frontface, and on the water surface, as shown in FIG. 6, the transceiverfloats in an attitude with the upper front side down and the lower rearside up. With this attitude, since the electrodes 35 sink in the water,they are electrically conducted by conductivity of water. As a result,the LED 41 flashes. By the flashing of the LED 41, the translucentsection 13A on the lower part of the gasket 13 flashes. Since thetranslucent section 13A is on the water surface and also directedupward, its presence can be displayed such that a user who dropped thetransceiver 1 into the water can easily find it.

FIG. 7 are diagrams illustrating another installation form of theelectrodes 35. FIG. 7A is a left sectional view of the vicinity of thespeaker grill 16 of the front housing 11A, and FIG. 7B is a diagram ofthe vicinity of the speaker grill 16 of the front housing 11A seen frombehind the speaker 30.

In the embodiment in FIG. 7, a through hole exclusively for theelectrode 35 is not opened, but the electrode 35 is made to pass througha gap between the speaker fitting hole 112 and the speaker 30. Theelectrode 35 is formed in a stair-like shape having one step. Theelectrode 35 reaches the outside from the inside of the front housing11A (speaker 30 and the net 31) along the outer periphery of the speakerfitting hole 112 and then, bends to the center side of the speaker 30and reaches the front face of the speaker 30 and bends again andprotrudes to the back side of the fin 32.

In above embodiments, a self-flashing LED is used as the LED 41, but anormal LED may be used, and a flashing circuit may be disposed outsideof the LED separately.

In above embodiments, a handy transceiver for maritime communicationswas explained as an example, but the portable electronic device of thepresent invention is not limited to the handy transceiver.

Also, the transceiver 1 of above embodiments have a structure which iswater-proof and floats on the water (has a specific gravity smaller thanwater), but the present invention can be also applied to a portableelectronic device with the specific gravity equal to or larger thanwater.

What is claimed is:
 1. A portable electronic device comprising: a dropdetection part that detects drop of the device into the water; a lightemission part; and a light-emission control circuit that makes the lightemission part emit light when the drop detection part detects drop intothe water.
 2. The portable electronic device according to claim 1,wherein the light emission part is disposed on the side to be turned upby buoyancy when the device is dropped into the water; and the dropdetection part is disposed on the side to be turned down when the deviceis dropped into the water.
 3. The portable electronic device accordingto claim 2, wherein a buoyancy by which at least the light emission partcomes up to the water surface when the device is dropped into the wateris provided.
 4. The portable electronic device according to claim 2,further comprising: an antenna on a front side of the top face and aspeaker on a front face, wherein the drop detection part is disposedinside a speaker grill that covers the front of the speaker, and thelight emission part is disposed on the bottom face.
 5. The portableelectronic device according to claim 1, wherein the light-emissioncontrol circuit is provided with a delay circuit that keeps the lightemission part emitting light for a predetermined time after the dropdetection part does not detect drop into the water any longer.
 6. Theportable electronic device according to claim 1, further comprising: ahousing including a front housing, a rear housing and a gasket fitted toa joined part of the front housing and the rear housing, wherein thelight emission part includes a translucent section formed at a part ofthe gasket and a light emitting semiconductor element disposed insidethe housing.